Respiratory Hazards in Abrasive Blasting

Transcription

Respiratory Hazards in Abrasive Blasting
Safety In Abrasive Blasting
Webinar
Wednesday, March 27, 2013
Respiratory
Hazards in
Abrasive Blasting
William J. Mills
Earl A. Medina
Disclaimer
• The mention of any manufacturer or trade
name is for informational purposes only
and does not constitute endorsement or
approval by Dr. Mills, Mills Consulting, Inc.
or Northern Illinois University.
• This presentation has been prepared as a
public service and no compensation has
been received.
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OUTLINE
1. Abrasive Blasting Introduction
2. Types of Media
3. Types of Potential Hazards
4. Respiratory Hazards
5. Respiratory System
6. Particulate deposition
7. Occupation Exposure Limits (OEL)
8. IH Hierarchy of Control
9. Types of Respiratory PPE
10. Respiratory Protection Program
11. Conclusions
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Abrasive Blasting
*The use of abrasive material surface cleaning, removal or
preparation of a material
– Energy transfer using:
• Air pressure
• Centrifugal wheels
• Water pressure
– Wet blasting
– Hydroblasting
– Equipment depends upon:
• Specific application
• Type(s) of abrasive(s)
– e.g. “Sand
Blasting”
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Abrasive Blasting
Media Examples
NIOSH does not recommend use of sand containing >1% crystalline silica
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Potential Hazards
• General Construction
–
–
–
–
Slips/trips
Falls (elevated locations)
Noise
Foot protection
• Physical
– Temperature extremes
– Ergonomic
– Dermal
• Respiratory Hazards
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Respiratory Hazards
• Particulate Matter (PM)
– General
– Particle size
– Particle composition
• Confined Space
• Oxygen (O2) deficiency
• Potential Toxicity
• Carbon Monoxide (CO)
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Sources of Potential
Air Contaminants
• Base Material
– e.g., steel, aluminum, stainless steel, galvanized steel, coppernickel and other copper alloys
• Surface Coatings
– e.g., pre-construction primers, anticorrosive and antifouling
paints
• Abrasive Blasting Media
– e.g., coal slag, copper slag, nickel slag, glass, steel grit, garnet,
silica sand
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Example Surface Coating
Concentrations
Year 1
Year 2
Year 3
No. of Samples
4
11
4
Silica, crystalline
63,000
95,800
59,000
Arsenic
27.7
<23
<22
Beryllium
<0.44
<1.20
<0.89
Cadmium
7
3.58
1.16
Chromium
1,780
4,080
4,850
Chromium (VI)
0.36
7.36
3.39
Lead
135,000
172,000
175,000
Manganese
692
237
243
Nickel
48
14.5
10.6
Silver
<2.20
<6.3
<4.40
Titanium
128
64.6
558
Vanadium
8.56
9.95
10.7
*All results are
in ppm
Other potential components of concern:
Al, Ba, Co, Cu, Fe, Mg, Mo, P, Se, Na, Te, Tl , Y, Zn, Zr
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The Human
Respiratory
System
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PM
Particle Size Ranges
“RESPIRABLE PARTICULATE” (RP)
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Particle Deposition in
Respiratory System
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US Regulatory Issues
3 Primary OSHA Standards:
1. General Industry (29 CFR 1910)
2. Maritime (29 CFR 1915)
3. Construction (29 CFR 1926)
Other Examples:
• US EPA Regulations at 40 CFR
• State & Local Regulations & Codes
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US Occupational
Exposure Limits (OEL)
Factor of 300000 between TP and Be OELs
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Determining Hazard
Potential
• MSDS (now SDS)
– Carcinogens listed (for >0.1% by weight)
– ACGIH TLV also required to be listed
– Respiratory protection
• Chemical Analysis:
– Media
– Coating
– Substrate
• Scientific Literature
– Journals
– Government Agency Publications
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Pneumoconioses
• A group of interstitial lung diseases that
are caused by the inhalation of a range of
organic and non-organic dusts/fumes
which are then retained in the lungs. The
disease is a result of the lung tissue’s
reaction to the dust.
• The principal cause of the
pneumoconioses is work-place exposure
• Singular= Pneumoconiosis
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Respirable Particulate
Sampling Results
• 2013 Ceballos et al. JOEH
– 100% of analyzable RP samples exceed PEL
(5 mg/m3)
– Measured concentrations 75-25000 mg/m3
• 2006 Meeker et al. JOEH
– 100% of RP samples exceeded PEL
– Measured concentrations 30-5652 mg/m3
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IH Hierarchy for
Addressing Hazards
• Engineering Control examples
– Material substitution
– Enclosures
– Remote or automated blasting
– LEV
• Administrative Control examples
– Restrictions on work time
– Confined spaces entry protocols
• PPE
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Respiratory PPE
1. If controls not
feasible
2. Oxygen Deficient
Atmosphere
Respiratory PPE :
• Properly selected
based on task
• Individually fitted
• Properly maintained
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Do I need to wear a
respirator ?
• What is the hazard?
• What is the degree of the hazard
– What is expected range of concentrations?
– What is relevant OEL?
• Work requirements
• The user
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Types of Respirators
• Air Purifying Respirator (APR)
– Non-powered APR
– Powered Air Purifying Respiratory (PAPR)
• Atmosphere Supplying
– Supplied Air Respirator (SAR)
– Self Contained Breathing Apparatus (SCBA)
– Combination
Also: Positive Pressure vs. Negative Pressure
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APR/PAPR Examples
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SAR & SCBA Examples
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Assigned Protection
Factor (APF)
• APFs and Maximum Use Concentrations
(MUCs).
See: 29 CFR 1910.134
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Type of Respirator1, 2
Assigned Protection
Factors (APF)
Quarter mask Half mask
1.
Air-Purifying Respirator
5
2.
Powered Air-Purifying Respirator (PAPR)
3.
Supplied-Air Respirator (SAR)
Full facepiece
Helmet/Hood
50
10
—
50
• Demand mode
—
10
• Continuous flow mode
—
50
1,000
• Pressure-demand or other
—
50
1,000
• Demand mode
—
10
• Pressure-demand or other positive-
—
—
—
25/1,0004
1,000
Loose-fitting
facepiece
—
25
or Airline Respirator
50
—
25/1,000
—
25
—
—
50
—
positive-pressure mode
4.
Self-Contained Breathing Apparatus (SCBA)
50
10,000
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10,000
—
25
OSHA Respirator RequirementsAbrasive Blasting
• “Abrasive-blasting respirator” or “Particulate-filter
respirator” (“dust-filter respirator”)
• Abrasive blasting respirators = NIOSH Type CE SAR
• Required when:
– working in enclosed or confined spaces; or
– using abrasive media that contains more than one percent
crystalline silica.
• For other situations, abrasive blasters must be protected
with Type CE SAR or APR with HEPA (N-100) filters.
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Abrasive Blasting PPE
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NIOSH Type CE
Respirator Approvals
30 models (total) currently approved by NIOSH
Approved Vendors
• MSA
• Clemco Industries Corp.
• E.D. Bullard Company
• Avon-International Safety Instruments, Inc.
• RPB Limited
• 3M Company
Note: loose fitting Type CE Abrasive Blasting Respirators (hoods, helmets) DO
NOT need to be fit tested
Source: http://www2a.cdc.gov/drds/cel/cel_form_code.asp
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Photos of CE
Respirators-1
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Photos of CE
Respirators-2
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Photos of CE
Respirators-3
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Photos of CE
Respirators-4
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Respiratory Protection
Program
• OSHA 29 CFR 1910.134
– Required whenever respirators are required
to be worn
– Written program is required
– Additional program requirements
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Elements of a Respiratory
Protection Program
1.
2.
3.
4.
5.
6.
7.
8.
9.
Procedures for selecting respirators
Medical evaluations
Fit testing procedures
Instructions on Use of respirators
Procedures for cleaning and maintaining respirators
Procedures to ensure adequate air quality/quantity
Training of employees in the potential respiratory hazards
Training of employees in the proper use of respirators
Procedures for regularly evaluating the effectiveness of the
program.
10. Worksite Specific Procedures may be needed.
http://www.osha.gov/dts/osta/otm/otm_viii/otm_viii_2.html#4
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Fit testing
• Loose fitting (hoods, helmets) Type CE
Abrasive Blasting Respirators DO NOT
need to be fit tested
• Tight fitting Type CE DO need to be fit
tested
– Quantitative
– Qualitative
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Examples of Improper
Usage
• Facepiece seal leakage (not an issue with
CE hood respirators)
• Removal of respirator at wrong time in
hazardous atmosphere
• Improperly performing user seal checks
• Improperly repairing defective parts
• Improper air supply source (SAR)
• Improper air supply monitoring (SAR)
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SAR air needs to be of
acceptable quality
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Grade D Breathing Air
Required
• Compressed Gas Association (CGA)
Specification
Includes:
– Air quality requirements
– Monitoring requirements
• OSHA referenced requirement for SAR
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Temperature related
issues
• Heat related illnesses of bigger concern in
USA
• Emergency first aid training
• Prevention
– Rest periods
– Hydration
– Fitness
– Acclimatization
– Climate control
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Proper maintenance
• Quick pre-use inspection
– By person using respirator
• Clean between use
–
–
–
–
Keep visibly cleaned
Wet cleaning better
Do not use air pressure blowing
Take care in choosing cleaning agents
• Water and soap
• Methanol or isopropanol impregnated wipes
– May require vacuuming (with HEPA filtration)
– Performed by person wearing respirator or another properly trained &
authorized person
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Follow Respirator
User’s Guide
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Conclusion
•
Respiratory Hazards are due to
– PM concentrations
– Particle size
– PM content
•
Prevention is much better than Treatment
•
PPE used only if controls not effective in reducing exposures
•
APR N100 respirators of limited applicability
•
Type CE respirators optimized for abrasive blasting
- provide best combination of protection, ease of use and costs
• Respiratory Protection Program has specific required elements
•
Protection from potential respiratory hazards is possible
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Conclusion
•
Respiratory Hazards are due to
– PM concentrations
– PM content
• Media
• Coatings
• Substrates
•
Prevention is much better than Treatment
•
PPE used only if controls not effective in reducing exposures
•
APR N100 respirators of limited applicability
•
Type CE respirators optimized for abrasive blasting
- Provide best combination of protection, ease of use and costs
• Respiratory Protection Program has specific required elements
•
Protection is possible
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Thank you for
listening!
William J. Mills, III
Ph.D, M.Sc., CIH, C.Chem.
Phone: (708) 524-2166
Email:
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